Method for the hot measuring, during rolling, of a size of metal profiles

ABSTRACT

A method for the hot measuring of a transverse size of a metal profile to obtain a diameter and/or a mean thickness includes providing power with a sinusoidal current having at least two frequencies, a transmission element having at least two sections distinct and spatially separated from each other and disposed along a nominal axis of feed of the metal profile, generating an electromagnetic field with a desired profile of the force lines, and detecting a signal relating to the variations of the electromagnetic field due to the passage of the metal profile through the sections of the transmission element using a reception element having one or more sections distinct and spatially separated from each other and disposed along the nominal axis in a position of the transmission element.

FIELD OF THE INVENTION

The present invention concerns a method for the hot measuring, during rolling, of a transverse size of metal profiles, for example steel bars or tubes.

In particular, the present invention concerns a method that can be used to measure both the external diameter, in the case of bars and tubes, and also the mean and local thickness in the case where the metal profile is a tube.

BACKGROUND OF THE INVENTION

It is known to produce metal profiles such as steel tubes and/or bars by hot rolling. To control the rolling process it is useful to know, as the process is performed, a transverse size of the metal profiles, for example the mean diameter in the case of bars and/or the mean diameter and thickness in the case of tubes. This allows to intervene quickly to adjust the rolling process in order to obtain metal profiles with the desired diameter and/or thickness, as constant and uniform as possible.

It is known to make tubular elements starting from a full profile and making the axial hole by means of a mandrel. The subsequent step consists of reducing the section size of the desired tubular element. This operation is normally carried out by passing the tubular element thus obtained through one or more rolling stands.

This process can cause mainly two types of problem in the quality of the tubular element, both connected to a deviation in thickness.

A first problem concerns a deviation in thickness due to the eccentricity of the mandrel, when the axial hole is being made, with respect to the nominal section of the tubular element to be made.

A second problem concerns a deviation in thickness not due to any eccentricity between hole and section but due to localized circumferential variations in the thickness of the tubular element.

The deviation in thickness has a negative influence on the quality of the work. Moreover, the resistance and performance of the metal profile can also be influenced during use.

Different devices and methods are known, to measure a size of metal profiles, in particular a transverse size, directly and without contact, during hot rolling.

For example, devices are known that use a radiographic method, based on the use of gamma rays produced by radioactive sources. This method provides to use one or more pairs of radioactive sources and one or more radiation detectors. According to the radiation captured by the radiation detectors after the tubular element has passed through, an electric current is generated that is processed and digitalized by a measurement transducer and subsequently sent to a central processing system to calculate the thickness of the wall of the tubular element.

One disadvantage of such devices is the high costs and safety problems deriving from the use of radioactive substances and the subsequent disposal procedure.

Devices for measuring a transverse size are also known, which provide to use ultrasonic laser technology. In this case, a transmitter probe emits a pulsed laser beam which generates an ultrasonic wave, which is propagated from outside to inside the thickness of the metal profile, is reflected by the internal surface of the tubular element and returns toward the external surface. A laser interferometer determines the time taken by the ultrasonic wave to pass and, once the speed of propagation of the ultrasonic wave is known, the device is able to detect the thickness of the metal profile as a function of the passing time measured.

One disadvantage of ultrasonic laser devices is that they need an angular scan, and must therefore provide to move and partly rotate the support parts of the probes, to obtain the detection of the measurement on several surface portions of the metal profile to cover the entire circumference.

Another disadvantage of this technique is the sensitivity of the detection with respect to the position of the transmitter and receiver probes. Furthermore, the devices are generally rather expensive and difficult to manage and maintain.

Electromagnetic measuring devices with parasitic currents are also known. One or more transmission coils are generally used, which generate a magnetic field and one or more reception coils which detect the variations in the magnetic field induced. One disadvantage of known electromagnetic devices is that the measurement greatly depends on the relative position of the metal profile and sensor.

Another disadvantage of electromagnetic measuring devices with parasitic currents is that the measurement of a transverse size of a metal profile is influenced by the conductivity of the metal material of the profile measured. For this reason measuring devices with parasitic currents require specific and different calibrations according to the conductivity of the material of the profiles to be measured.

WO 2013/190360 describes an apparatus to detect the deviation in thickness in a section of a tubular metal element. The apparatus consists of at least three sensors of the electromagnetic type, each comprising a transmission coil and a reception coil, disposed distanced around the circumference of the tubular metal element which is measured. The transmission coil and the reception coil are disposed outside the wall of the tubular metal element measured. In this document, it is advantageous to provide that each of the sensors, which incorporates both the transmission and the reception coil, is associated with a respective rolling ring.

This document provides that there can be measurement apparatuses associated with each rolling stand, to perform the measurement simultaneously with each reduction in section. For each measurement on the same section, however, each measurement apparatus provides that each electromagnetic sensor operates on an angular portion of the section, for example 120° in the case of three sensors, to detect the local thickness of the tubular metal element. By comparing the three detections an indication is obtained if the thickness of the tubular metal element is constant or not over the whole circumference. The document does not provide that the transmission and reception coils that operate on the same measurement of the nominal section of the tubular metal element are located distanced from each other along the axis of the tubular element.

U.S. Pat. No. 3,693,075 describes a system and an apparatus to detect defects, eccentricity and wall thickness of tubular metal elements. The apparatus has a primary coil that emits an electromagnetic field that generates parasitic currents on the surface of the tubular metal element, and a secondary coil that detects the parasitic currents to obtain the desired information.

The primary coil and secondary coil are substantially in axis with respect to each other and disposed respectively on opposite sides with respect to the wall of the tubular metal element which is measured.

One purpose of the present invention is to provide a method for measuring the diameter and/or thickness of bars and tubes which allows to make the measurement under hot conditions efficiently.

Another purpose of the present invention is to provide a measuring method that allows to make the measurement independently of the position of the metal profile inside the measuring device used.

Another purpose is to provide a measuring method that is independent of the conductivity of the material measured.

Another purpose is to obtain a measuring method that is substantially independent both of the speed and also of the temperature of the metal profile and/or the particular type of material used, if the material is not ferromagnetic, for example for non-ferrous metals or stainless steels, and which is independent of the speed and temperature when the latter is above Curie temperature, in the case of other types of materials.

Another purpose of the present invention is to provide a measuring method that can measure the local thickness of a metal profile, such as a tube, in different angular positions simultaneously.

The Applicant has devised, tested and embodied the present invention to overcome the shortcomings of the state of the art and to obtain these and other purposes and advantages.

SUMMARY OF THE INVENTION

The present invention is set forth and characterized in the independent claims, while the dependent claims describe other characteristics of the invention or variants to the main inventive idea.

In accordance with the above purposes, a method is provided for the hot measuring, during rolling, of a transverse size of metal profiles, such as for example solid bars or tubes.

According to the present invention, the method for the hot measuring, during rolling, of a transverse size of a metal profile such as a tube or a solid bar, to obtain at least the measurement of a diameter and/or a thickness of the metal profile, provides to power with a sinusoidal current having at least two frequencies, a transmission element having at least two sections distinct and spatially separated from each other, disposed along a nominal axis of feed of the metal profile and operating on the same nominal measurement of transverse size, and to generate with the transmission element an electromagnetic field with a desired profile of the force lines.

Both the transmission element and the reception element have a section shape, advantageously but not necessarily circular, defining a transit hole of a larger size than the diameter of the metal profile on which the measurement is performed, and inside which the metal profile is made to transit.

The method also provides to detect a signal relating to the variations of the electromagnetic field due to the passage of the metal profile through the sections of the transmission element by means of a reception element having one or more sections distinct and spatially separated from each other and disposed along the nominal axis in a position comprised in the overall longitudinal bulk of the transmission element.

The expression “in a position comprised in the overall longitudinal bulk of the transmission element” means that the reception element is disposed, in the direction of feed of the metal profile, always in an intermediate position between two transmission elements, and in any case contained longitudinally inside the extremes defined by the transmission elements. Thanks to this configuration, the force lines of the fields transmitted by the transmission elements can be conveyed optimally on the reception element, and not dispersed outside, making the measurement extremely effective and precise.

The expression “operating on the same nominal measurement of transverse size” means that the two sections of the transmission element are disposed spatially separate from each other along the axis of feed of the metal profile but between them no reduction in section of the metal profile takes place; therefore, although they operate on two distinct sections of the metal profile, the two sections have the same nominal transverse size.

According to one formulation of the present invention, the method also provides to carry out a normalization and non-dimensionalization of the value of the flow of electromagnetic field detected with respect to the value of the current for every frequency, to define a mathematical model on the basis of the normalized and non-dimensionalized values of flow, and to perform a homographic transformation to determine a correspondence between real non-dimensionalized values and ideal non-dimensionalized values defined by the mathematical model. The method according to the invention also provides to process the data obtained from the homography to calculate the diameter and/or the mean thickness of the metal profile.

In this way, the measurement of a transverse size of the physical size of said metal profile is de-constrained from the physical sizes of the transmission element and the reception element, thus allowing to have a more reliable measurement.

According to some embodiments, the homographic transformation is performed on the basis of parameters derived from a first level of calibration at least of the transmission element and of the reception element.

According to some embodiments, the first level of calibration provides to detect at least three measurements of the electromagnetic reaction field, respectively one measurement with no metal profile present and two measurements with two metal profiles present as a solid bar, wherein the measurements are performed for each frequency of the current.

According to some embodiments, the method provides to detect signals relating to the variations of the electromagnetic field due to the passage of a tube-like metal profile with segmented coils corresponding to a determinate sector obtained by dividing into equal parts a circular crown, disposed around the reception element, to perform at least the measurement of a local thickness of the tube-like metal profile.

According to some embodiments, the method provides to perform a compensation of the position of the tube-like metal profile with respect to the transmission element and the reception element in order to render the measurement of a transverse size independent of the alignment of the metal profile with respect to the nominal axis. This allows to obtain a reliable measurement even if the metal profile being measured is not coaxial with the reception element.

According to some embodiments, the method also provides to perform an estimation of the eccentricity of the metal profile measured, to determine at least a local wall thickness for each signal detected by each segmented coil.

In this way it is possible to determine the entity of the possible eccentricity of the tube-like metal profile and in which direction it is oriented, thus allowing to adjust the working machines of the metal profiles that are located upstream of the transmission and reception element in order to correct working errors.

The method according to the invention therefore allows, with a simultaneous measurement, to assess both the external diameter for metal profiles, both bars and tubes, and also the mean and local thicknesses of tube-type metal profiles.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other characteristics of the present invention will become apparent from the following description of some embodiments, given as a non-restrictive example with reference to the attached drawings wherein:

FIG. 1 is a partly sectioned perspective view of a device for the hot measuring of a size of metal profiles in accordance with embodiments described here;

FIG. 2 is a section view of a device for the hot measuring of a size of metal profiles in accordance with embodiments described here;

FIG. 3 is a schematic view of one part of a device for the hot measuring of a size of metal profiles in accordance with embodiments described here;

FIG. 4 is a schematic view of one part of a device for the hot measuring of a size of metal profiles in accordance with variant embodiments described here;

FIG. 5 is a schematic view of one part of a device for the hot measuring of a size of metal profiles in accordance with other variant embodiments described here;

FIG. 6 is a cross section view of a device for the hot measuring of a size of metal profiles;

FIG. 7 is a partly sectioned perspective view of a device for the hot measuring of a size of metal profiles in accordance with other embodiments described here;

FIG. 8 is a section along the section plane P of FIG. 7;

FIG. 9 is a section along the section plane P of FIG. 7 in accordance with other embodiments described here.

To facilitate comprehension, the same reference numbers have been used, where possible, to identify identical common elements in the drawings. It is understood that elements and characteristics of one embodiment can conveniently be incorporated into other embodiments without further clarifications.

DETAILED DESCRIPTION OF SOME EMBODIMENTS

We shall now refer in detail to the various embodiments of the present invention, of which one or more examples are shown in the attached drawing. Each example is supplied by way of illustration of the invention and shall not be understood as a limitation thereof. For example, the characteristics shown or described insomuch as they are part of one embodiment can be adopted on, or in association with, other embodiments. It is understood that the present invention shall include all such modifications and variants.

FIGS. 1-9 are used to describe embodiments of a device 10 for hot measuring a transverse size of metal profiles 12. In the present description the definition “metal profiles” means elements having a transverse size much smaller than their longitudinal development, such as steel bars or tubes for example.

The device 10 can be used to measure the transverse size of metal profiles 12 in transit and can be disposed, for example, in an inter-stand segment, that is, between two successive rolling stands, or at the end of the rolling process to measure the final size of the product obtained.

FIG. 2 is used to describe embodiments of an apparatus 50 for hot measuring, during rolling, a transverse size of metal profiles 12 comprising the device 10 and a control and command unit 40.

The control and command unit 40 can be configured both to feed the device 10 with the electric energy it needs for functioning, and also to process the signals detected by the device 10.

FIGS. 1-7 are used to describe embodiments of a measuring device 10 comprising a transmission element 14, having at least two sections, but there can also be 3, 4 or more—14 a, 14 b, 14 c, 14 d—distinct and spatially separated from each other, configured to generate an electromagnetic field, and a reception element 18, located in an intermediate position in the overall bulk of the transmission element 14. According to some embodiments, the reception element 18 can have one or more sections 18 a, 18 b, distinct and spatially separated from each other.

The transmission element 14 and the reception element 18 are disposed, substantially aligned and coaxial with respect to each other, along a nominal feed axis Z of the hot metal profile 12 in transit, arriving from rolling or other type of hot deformation.

Both the transmission element 14 and the reception element 18 have an advantageously, but not necessarily, circular section, defining a transit hole for the metal profile 12.

The transmission element 14 and reception element 18 have respective internal surfaces 24, 28, which define a transit volume of the metal profile 12, inside which the force lines of the electromagnetic field generated by the transmission element 14 are disposed substantially parallel to the nominal feed axis Z of the metal profile 12.

The reception element 18 is configured to detect the variations in the reaction electromagnetic field, generated by the currents induced on the metal profile 12, due to the passage of the metal profile 12 inside the electromagnetic field generated by the transmission element 14.

According to embodiments described using FIGS. 1 and 2, a transmission element 14 can be provided having two distinct sections 14 a, 14 b and a reception element 18 having a single section 18 a disposed in an intermediate position between the two sections 14 a, 14 b of the transmission element 14.

According to embodiments described using FIG. 3, a transmission element 14 can be provided that is divided into three distinct sections, 14 a, 14 b, 14 c, and a reception element 18 with a single section 18 a positioned drowned inside the central section 14 b of the transmission element 14.

According to possible variant embodiments described using FIG. 4, a transmission element 14 can be provided that is divided into three distinct sections, 14 a, 14 b, 14 c, and a reception element 18 with a single section 18 a disposed in an intermediate position, for example between two sections 14 a, 14 b of the transmission element 14.

According to other variant embodiments described using FIG. 5, a transmission element 14 can be provided that is divided into four distinct sections, 14 a, 14 b, 14 c, 14 d, and a reception element 18 divided into two sections 18 a, 18 b disposed in an intermediate position between adjacent pairs of sections 14 a, 14 b, 14 c of the transmission element 14.

According to other variant embodiments, not shown in the drawings, a transmission element 14 can be provided that is divided into more than four distinct sections and a reception element 18 divided into more than two distinct sections, positioned between adjacent portions of the transmission element 14, or drowned inside a section of the transmission element 14.

According to embodiments described using FIGS. 1 and 2, the transmission element 14 and the reception element 18 can be coils, or spirals of a substantially cylindrical shape, with respective radiuses R1 and R2.

The transmission element 14 can consist of a spiral or coil with an overall extension L1 along the nominal axis Z, greater in size than an overall extension L2 of the reception element 18.

According to embodiments described using FIG. 2, radius R2 of the reception element 18 is substantially equal to radius R1 of the transmission element 14.

According to variant embodiments, radius R2 of the reception element 18 can be bigger or smaller than radius R1 of the transmission element 14.

According to some embodiments, the sizes of the transmission element 14, in particular the length L1, radius R1 and/or number of spirals of the coil, can be suitably chosen so that the electromagnetic field generated by the transmission element 14 has a predetermined profile. The profile of the electromagnetic field is designed so that the measurement of the size of the metal profile 12 that passes through it does not depend on its position with respect to the nominal axis Z.

FIG. 6 is used to show possible positions of a metal profile 12 inside the device 10. A possible position is the one indicated by number 16′, which corresponds to a position perfectly aligned along the nominal axis Z, in which the metal profile 12 is perfectly coaxial to the device 10.

Numbers 16″ and 16′″ indicate possible positions in which the metal profile 12 or a portion of it can be found as it passes through the device 10, in which positions the metal profile 12 is eccentric with respect to the device 10. In particular, the real axis of feed of the metal profile 12 may not coincide with the axis of the transmission element 14 and reception element 18, which would distort the measurement of the device 10 and make it imprecise and unreliable.

It can also be seen that, depending on the size of the metal profile 12 being measured, the index of relative filling of the metal profile 12 and the internal surfaces 24, 28 of the transmission element 14 and the reception element 18 may increase or decrease.

By index of relative filling we mean the ratio between the area defined by the metal profile 12 intersecting a plane (X, Y) perpendicular to the nominal axis Z and the area defined by the internal surfaces 24, 28 on the same plane (X, Y). The lower the value of the index of relative filling, the greater the probability that the metal profile 12 will be misaligned, during measurement, with respect to the nominal axis Z, and the greater the distance of the center of the metal profile 12 from the nominal axis Z.

When the index of relative filling has a low value, the precision and sensitivity of the measuring device 10 is consequently reduced.

Using the geometric configuration described above, with the generation of an electromagnetic field with a profile of the force lines having a desired longitudinal development, allows to make the position of the metal profile 12 with respect to the axis of the transmission element 14 and reception element 18 substantially non influential.

Therefore, the measurement is reliable, precise and repeatable for any measurement of the metal profile 12 in the range of measurements compatible with the size of the transmission element 14 and reception element 18, in particular with the size of the respective axial holes.

A current 20 passes through the transmission element 14, which induces the generation of an electromagnetic field inside the volume defined by the internal surfaces 24, 28.

The electromagnetic field generated by the current 20 circulating in the transmission element 14 induces parasitic currents, mainly azimuth, in the metal profile 12. The parasitic currents in turn generate a reaction field, which can be detected by means of its flow concatenated by the reception element 18, at the heads of which an electromotive force occurs. A signal 22 relating to the electromotive force can be sent to the control and command unit 40 to be subsequently processed so as to obtain the measurement of thickness and diameter.

According to other embodiments, the transmission element 14 can be designed so that the electromagnetic field generated has a profile such that the reaction field measured by the reception element 18 is substantially independent of the position of the metal profile 12 inside the device 10.

By suitably processing the signals relating to the electromotive force 22 and the current 20, it is possible to assess both the mean thickness S1, generally indicated by WT (Wall Thickness) of a metal profile 12 along the circumference, if the metal profile 12 is a tube, and also the external diameter D, or OD (Outer Diameter) if the metal profile 12 is a tube or bar.

Advantageously, the device 10 according to the present invention can therefore be used during the hot rolling process to measure a transverse size of both tubes and bars.

According to embodiments described using FIGS. 1, 2 and 7, the device 10 can comprise a casing 30 that surrounds at least the transmission element 14 and the reception element 18, which can function as a screen, so as to prevent the magnetic field from inducing currents outside the device 10 as well.

According to embodiments described using FIG. 7, the measuring device 10 can also comprise a thermostat system 29, configured so as to keep the size and conductivity of the casing 30 substantially uniform, and in any case within acceptable tolerance limits, stabilizing the temperature of the casing 30 which influences them.

According to other embodiments, the device 10 can comprise reception devices, or reception coils 31, configured as segments. According to embodiments described using FIGS. 7 and 8, the reception coils 31 can be coils with a segmented shape, corresponding to the sectors obtained by dividing a circular crown into equal parts, disposed around the reception element 18.

Since the segmented reception coils 31 are positioned around the reception element 18, and since the flow of the magnetic field through the internal surface 28 of the reception element 18 is the same that passes through the infinite surface external to it, only a part of the flow of magnetic field passes through each segmented reception coil 31. In particular, the flow that passes through each segmented reception coil 31 is at least partly determined by the characteristics of the portion of metal profile 12 facing it.

According to embodiments described using FIGS. 7 and 8, twenty segmented coils 31 can be provided, each corresponding to a circular sector of 18°.

According to a variant embodiment described using FIG. 9, four segmented coils 31 can be provided, indicated for example by the numbers 31 a, 31 b, 31 c, 31 d, each corresponding to a circular sector of 90°.

According to other variant embodiments, any number whatsoever of segmented coils 31 can be provided, comprised between two and twenty, or even more than twenty.

According to some embodiments, the segmented reception coils 31 can be serially connected in groups to constitute measuring coils, each consisting for example of two, three, four, five or more segmented coils 31. According to embodiments described by way of non-restrictive example with reference to FIG. 9, by means of the four segmented coils 31 a, 31 b, 31 c, 31 d it is possible to detect four different magnetic field flows, each relating to an angular sector of the metal profile 12 measured, in this case for example, four flows relating to arcs of circumference of 90°.

In this way it is advantageously possible to assess also the local thickness of a metal profile 12, in this case a tube, along its circumference. In fact, a single simultaneous measurement is made on the field flows concatenated with the reception element 18 and the segmented coils 31 a, 31 b, 31 c, 31 d, and the data are processed to obtain the information concerning the measurements of diameter and thickness.

In particular, the external diameter D and the mean thickness S1 and local thickness are evaluated by the control and command unit 40 processing the signal 22 received, which signal relates to the electromotive force generated at the heads of the reception element 18.

This allows to detect deviations in thickness of the tubular metal profile 12 due for example to the eccentricity of the mandrel or undulation defects of the so-called “daisy” type.

The control and command unit 40 can be used to implement a method for hot measuring a transverse size of metal profiles.

The measuring method according to the present invention comprises a procedure relating to the calibration of the device 10 and a procedure relating to the implementation of a calculus algorithm to detect the values of quantities desired.

According to some embodiments, the control and command unit 40 comprises a feed unit 42 configured to supply the transmission element 14 with the current 20 necessary for the induction of a longitudinal electromagnetic field.

The feed unit 42 can comprise a source for feeding electric energy 44, for example a connection to the traditional electric network, or a system to accumulate electric energy.

According to some embodiments, the current 20 feeding the elements that generate the electromagnetic field can be an alternate current with a multi-frequency spectrum, obtained by overlapping at least two sinusoidal currents having different frequencies F1, F2, of which the first frequency F1 is much greater than the second frequency F2.

According to some embodiments, three or more frequencies can be provided, which can be used for example to find other information concerning the geometry of the metal profile 12 to be measured, or to self-calibrate the device 10, and/or to eliminate the common modes of the reaction field.

According to some variant embodiments, it may be provided, for example if the metal profile 12 to be measured is a bar, to use two frequencies that are very close to each other, so as to be able to detect a possible ovalization of the metal profile 12.

According to some embodiments that provide to use two frequencies F1, F2 of which one is greater than the other, the first bigger frequency F1 can be chosen so that the depth of penetration corresponding to it for the conductivity expected and for the range of metal profiles 12 to be measured is much lower than an expected minimum thickness.

According to some embodiments, the second lower frequency F2 can be chosen so that the depth of penetration corresponding to it is in a determinate ratio with the expected thickness for the given format of a metal profile 12 currently being measured, so as to optimize the variations in modulus and phase of the signal 22 detected relating to the electromotive force.

According to some embodiments, the control and command unit 40 also comprises a processing unit 46, configured to process the signal 22 detected and to implement a calculus algorithm to obtain at least the values of diameter D, mean thickness S1 and local thickness of the metal profile 12 measured.

According to some embodiments, the processing unit 46 can be any data processing system whatsoever, a controller, microcontroller, processor or microprocessor usable in the control field.

According to some embodiments, the control and command unit 40 can also comprise a data storage unit 48, configured to memorize the data received from the device 10 to be processed, and the parameters needed to calibrate the device 10.

The signal 22 relating to the electromotive force is detected by the reception element 18 and can be amplified by a high impedance entrance circuit to be subsequently digitalized and processed by the processing unit 46.

The calculus algorithm provides a first phase of synchronous demodulation of the signal 22 relating to the electromotive force and the signal of the current 20, which identifies the moduli and phases of the components of the signal 22 for each of the frequencies of the current 20 set. In the same way, a voltage signal proportional to the current 20 is amplified, digitalized and processed by a digital synchronous processor.

A second phase of the algorithm provides to find the “phasor” of the flow of the magnetic field from the value of the electromotive force induced, with the frequencies of the current 20 set being known.

The term “phasor” means a complex number representable as vector in the complex plane that represents the Steinmetz transform of a well-defined pulsation sinusoidal function.

A third phase of the algorithm provides to normalize the value of the flow of the magnetic field obtained in the previous phase with respect to the corresponding phasor of the current. In this way the effect of possible variation is eliminated, due for example to the thermal drift of the impedance of the transmission element 14.

Subsequently, a second normalization is carried out, so as to non-dimensionalize the value of flow of the magnetic field, using a reference value relating to a normalized flow obtained without a metal profile 12 inside the device 10. The value of normalized flow without a metal profile 12 inside the device 10 can be obtained during the calibration step of the device 10 and memorized in the data storage unit of the control and command unit 40.

This pass allows to de-constrain the processing of the data from the physical parameters of the measuring device 10 and to return to a non-dimensional mathematical model.

The algorithm also provides a fourth phase of defining an ideal theoretical model used to calculate, starting from the normalized and non-dimensionalized flows, the value of the flow of the magnetic field in the reception element 18 as a function of the mean external radius R4, the mean internal radius R3 and the conductivityσ.

To calculate the value of flow of the magnetic field, a homographic transformation is also carried out, so as to determine a correspondence between the real non-dimensionalized phasors previously calculated and the non-dimensional phasors of the ideal model. The definition “homographic transformation” means a consistent transformation, which has the properties to put in biunivocal relation the points of two projective spaces of the same size, such that the shapes of one space are the same kind as the corresponding shapes of the other.

The parameters needed to perform the homographic transformation can be found by calibrating the device 10, in particular by a first level of calibration, which will be explained in more detail hereafter.

The measurement algorithm provides a fifth phase in which the normalized values of the flow measured by means of the homographic transformation are transformed into the corresponding ideal values.

The component to the first higher frequency F1 of the ideal flow is processed by the processing unit 46, which implements a suitable resolution algorithm to find the mean external radius R4 of the metal profile 12 being measured.

The component to the second lower frequency F2 of the ideal flow is processed by the processing unit 46, which implements a suitable resolution algorithm to find the mean internal radius R3 of the metal profile 12 being measured.

Finally, in phase six, the value of the mean thickness S1 can be calculated from the difference between the value of the mean external radius R4 and the value of the mean internal radius R3.

Advantageously, knowing the value of the mean external radius R4, the value of the external diameter D can also easily be calculated. The measuring device 10 can therefore also be used to measure the external diameter D of a solid bar.

If the metal profile 12 is a tube, the calculus algorithm can also provide phases to process the signal received to calculate the local thickness of the metal profile 12 being measured, using signals 23 relating to the flows of field detected by the segmented coils 31, 31 a, 31 b, 31 c, 31 d. In particular, a value of eccentricity of the metal profile 12 can be estimated.

While the flow obtained on the reception element 18 is not appreciably affected by a possible misalignment of a metal profile 12 to be measured with respect to the nominal axis Z, the flow obtained on the segmented reception coils 31, 31 a, 31 b, 31 c, 31 d can be influenced by the position of the metal profile 12 with respect to the segmented reception coils 31, 31 a, 31 b, 31 c, 31 d themselves. In fact, the closer the metal profile 12 is to a segmented reception coil, 31, 31 a, 31 b, 31 c, 31 d, the more the segmented reception coil 31, 31 a, 31 b, 31 c, 31 d is concatenated with a greater portion of the reaction flow produced by the parasitic currents induced in the metal profile 12.

The calculus algorithm to determine the local thickness provides a first phase of compensating the position of the metal profile 12 inside the measuring device 10, which is carried out by exploiting the symmetry of the effect of the position on two opposite segmented coils 31, 31 a, 31 b, 31 c, 31 d, for example on segmented coils 31 a and 31 c (FIG. 9). According to some embodiments, the flow values detected by the segmented coils 31, 31 a, 31 b, 31 c, 31 d are reported on a complex plane. Since the points on the complex plane representing said flows move along a straight line as the direction and entity of the misalignment varies, the aim of the compensation is to move the point relating to a determinate segmented coil 31, 31 a, 31 b, 31 c, 31 d, obtained for a certain misalignment, to the point which would be obtained with the metal profile 12 perfectly centered on the nominal axis Z.

To determine how to move the point, it is possible to exploit the symmetry between two opposite segmented coils 31, 31 a, 31 b, 31 c, 31 d and to consider, for each pair, a difference vector between the two points relating to the concatenated flows of the segmented coils 31, 31 a, 31 b, 31 c, 31 d on the complex plane. The modulus of the difference vector considered quantifies the distance between the points, while the direction coincides with the straight line on which the points move. The point we would have if the metal profile 12 were centered, thanks to symmetry, is half-way between the two points relating to the concatenated flows of each pair of opposite segmented coils 31, 31 a, 31 b, 31 c, 31 d. In the case of FIG. 9 for example, if the concatenated flows of the segmented coils 31 a, 31 c are considered, it is sufficient to subtract half of the difference vector, calculated between the points of the flows detected of the segmented coils 31 a, 31 c identified on the complex plane, from the flow detected by the segmented coil 31 a, in order to obtain the compensated value of the flow for the segmented coil 31 a.

According to some embodiments, to compensate the position it is possible to use a parameter obtained by a second level of calibration, explained in more detail hereafter in the description.

The calculus algorithm also provides a first phase in which a signal 23 relating to the electromotive force induced at the heads of each segmented coil 31, 31 a, 31 b, 31 c, 31 d is processed in the same way as described previously with regard to the signal 22 detected by the reception element 18, until a value of normalized, non-dimensionalized flow, relating to an ideal model for each of the frequencies used is obtained for each signal.

The parameters needed for normalization and homographic transformation, in this case too, can be obtained by the first level of calibration, performed for each segmented coil 31, 31 a, 31 b, 31 c, 31 d.

In a subsequent phase, described for example using FIG. 9, the calculus algorithm provides to find, for each segmented coil 31 a, 31 b, 31 c, 31 d, the internal radiuses R5, R6, R7, R8 and hence the value of the mean internal radius R3 as the arithmetic mean of the values of the internal radiuses R5, R6, R7, R8.

Using the signals 23 found by the segmented coils 31 a, 31 b, 31 c, 31 d and the signal 22 detected by the reception element 18, it is also possible to perform an estimation of a possible eccentricity of a tubular metal profile 12 measured.

Knowing the measurement of the mean values obtained with the reception element 18, it is in fact possible to calculate an eccentricity index, corresponding to the ratio between each value of the internal radiuses R5, R6, R7, R8 obtained with the segmented coils 31 a, 31 b, 31 c, 31 d and the value of the mean internal radius R3. For each segmented coil 31 a, 31 b, 31 c, 31 d it is therefore possible to obtain a non-dimensional value that contains the information on the thickness of the part of the metal profile 12 in the area under the corresponding segmented coil 31 a, 31 b, 31 c, 31 d.

If there are more than four segmented coils 31, as for example in FIG. 8, for each of them the calculus algorithm provides to find the corresponding internal radius and hence the mean radius and the eccentricity index.

The value obtained is linearly dependent on the modulus of eccentricity so that, by means of a simple linear function, it is possible to obtain from the non-dimensional index a number that is coherent with the sizes of the tube. The parameters that must be used in the linear function can be identified by means of a third level of calibration. Using this calculation, only an estimate of the internal radius can be obtained, and hence of the local thickness, but it can be enough to detect the presence of an eccentricity and a non-dimensional index which quantifies it to be able to control the process and to produce non-eccentric tubes.

The eccentricity vector can therefore be calculated starting from the mean internal radius R3, the internal radiuses R5, R6, R7, R8 and the mean external radius R4.

First of all are calculated the local wall thicknesses S5, S6, S7, S8 relating to each segmented coil 31 a, 31 b, 31 c, 31 d as the difference between the mean external radius R4 and the internal radiuses R5, R6, R7, R8.

Subsequently, the mean thickness S1 is also calculated, as the difference between the mean external radius R4 and the mean internal radius R3.

Finally, by subtracting from the four local wall thicknesses S5, S6, S7, S8 the mean wall thickness S1, it is possible to assess and define the components of the eccentricity vector, and therefore find the modulus and phase of said vector.

In this way, advantageously, it is possible to determine if the metal profile 12 measured is eccentric, and at the same time to quantify the entity of the eccentricity and what direction it faces, so as to be able to intervene during the rolling process to solve problems of misalignment.

The calibration of the device 10 comprises three distinct levels to obtain the corresponding parameters needed for the homographic transformation, for compensating the position and for detecting and estimating the eccentricity.

According to some embodiments, the first level of calibration provides to find three values relating to the magnetic flow in known conditions. The values can be found using two solid bars with different diameters, known with precision, and detecting the measurement of the flow with no metal profile 12 present in the device 10. According to some embodiments, the diameters of the bars used can be chosen so as to define the extremes of the field of measurement provided for a given measurer; the nominal value expected must therefore be comprised in the range thus defined. For example, if the nominal external diameter D is 100 mm, then the diameters of the bars used for calibration can be equal respectively to 80 mm and 120 mm.

According to some embodiments, the bars used have the same conductivity and are made of the same raw material.

The first level of calibration therefore consists of measuring the flow values at the lowest frequency F1 and the highest frequency F2 without anything inside the measuring device 10, and with two different solid reference bars.

According to some embodiments, the second level of calibration is used to assess a parameter that can be used for example to compensate the position of a metal profile 12 with respect to the nominal axis Z. For this purpose a measurement is made using a non-eccentric tube of known sizes, moved by a certain amount from the axis Z of the device 10. The parameter is determined by a minimum problem, with the aim of making the difference minimum between the compensated values of the flow on the segmented coils 31, 31 a, 31 b, 31 c, 31 d.

According to some embodiments, the third level of calibration provides to perform a measurement on a tube with known eccentricity, facing in a known direction. For example, according to embodiments described using FIG. 9, by putting in relation the internal radiuses R5, R7, obtained from the flows measured on the segmented coils 31 a, 31 c, with the values of internal radius R3 of the eccentric tube, the coefficients are obtained through linear interpolation for estimating and assessing the eccentricity.

According to some embodiments, the parameters obtained by means of the different levels of calibration can be memorized in the data storage unit 48 to be subsequently used for implementing the calculus algorithm.

It is clear that modifications and/or additions of parts may be made to the device for hot measuring, during rolling, a transverse size of metal profiles as described heretofore, without departing from the field and scope of the present invention.

It is also clear that, although the present invention has been described with reference to some specific examples, a person of skill in the art shall certainly be able to achieve many other equivalent forms of device for hot measuring, during rolling, a transverse size of metal profiles, having the characteristics as set forth in the claims and hence all coming within the field of protection defined thereby. 

The invention claimed is:
 1. A method for the hot measuring, during rolling, of a transverse size of a metal profile to obtain at least one of a measurement of a diameter or a measurement of a mean thickness, of said metal profile, comprising: powering with a sinusoidal current having at least two frequencies, a transmission element having at least two sections distinct and spatially separated from each other, disposed along a nominal axis of feed of the metal profile and operating on a same nominal measurement of transverse size of the metal profile; generating with said transmission element an electromagnetic field with a desired profile of force lines; detecting a signal relating to variations of said electromagnetic field due to passage of said metal profile through said sections of said transmission element by means of a reception element having one or more sections distinct and spatially separated from each other and disposed along said nominal axis in a position comprised in an overall longitudinal value of said transmission element along said nominal axis, wherein both the sections of the transmission element and also the reception element are spirals or coils of a cylindrical shape and define a transit hole of a larger size than the diameter of the metal profile on which the measurement is performed, and inside which the metal profile is made to transit; normalizing and non-dimensionalizing a flow value of said electromagnetic field detected with respect to a value of said current for every frequency, wherein said flow value of said electromagnetic field is non-dimensionalized using a reference value relating to a normalized flow obtained without a metal profile; defining a mathematical model on the basis of the normalized and non-dimensionalized flow value; performing a homographic transformation to determine a correspondence between real non-dimensionalized values and ideal non-dimensionalized values defined by the mathematical model in order to de-constrain said measurement of a transverse size of said metal profile from the physical sizes of said transmission element and said reception element; and processing data obtained from the homographic transformation to calculate said diameter and/or said mean thickness of said metal profile.
 2. The method as in claim 1, wherein said homographic transformation is performed on the basis of parameters derived from a first level of calibration at least of said transmission element and of said reception element.
 3. The method as in claim 2, wherein said first level of calibration detects at least three measurements of said electromagnetic field, respectively one measurement with no metal profile present and two measurements with two metal profiles present as a solid bar, said at least three measurements being performed for each of said frequencies of the current.
 4. The method as in claim 2, including detecting signals relating to the variations of said electromagnetic field due to the passage of a tube-like metal profile with segmented coils corresponding to a determinate sector obtained by dividing into equal parts a circular crown, disposed around said reception element to perform at least the measurement of a local thickness of said tube-like metal profile, and processing said signals detected with said segmented coils by normalization, non-dimensionalization and homographic transformation using the parameters obtained from said first level of calibration.
 5. The method as in claim 4, including performing a compensation of the position of said tube-like metal profile with respect to said transmission element and said reception element in order to render said measurement of a transverse size independent of the alignment of said metal profile with respect to said nominal axis.
 6. The method as in claim 5, wherein said compensation of the position is performed using at least one parameter obtained from a second level of calibration at least of said transmission element and said reception element, which provides to detect at least one measurement of the reaction electromagnetic field in the presence of a non-eccentric metal profile and with known sizes, displaced with respect to said nominal axis.
 7. The method as in claim 1, including detecting signals relating to the variations of said electromagnetic field due to the passage of a tube-like metal profile with segmented coils corresponding to a determinate sector obtained by dividing into equal parts a circular crown, disposed around said reception element to perform at least the measurement of a local thickness of said tube-like metal profile.
 8. The method as in claim 7, including performing an estimation of the eccentricity of said metal profile to determine at least a local wall thickness for each signal detected by each segmented coil.
 9. The method as in claim 8, wherein said estimation of the eccentricity is performed by using at least one parameter obtained from a third level of calibration at least of said transmission element and said reception element, which provides to detect at least one measurement of said electromagnetic field in the presence of a tube-shaped metal profile with known sizes having a known eccentricity and oriented in a known direction. 